Antoine Hage’s Post

🚀 Exciting News! 🚀 I am thrilled to announce that our recent paper, co-authored with Professor Biswajit Paul, has been posted on arXiv: "PT-symmetry of Particle Mixing Theories and the Equation of Motion Matrix". 📄 [Read the full paper here](https://lnkd.in/dZyvWxDJ) 🔍 Abstract:Our study delves into the PT-symmetry in particle mixing theories and its impact on the equation of motion matrix. A non-Hermitian complex scalar model has been used to illustrate the states of the model. 💡 This research offers new insights into the theoretical framework of particle physics, potentially impacting how we understand and model these fundamental processes. I invite you to read our paper and share your thoughts or feedback. Looking forward to engaging discussions and potential collaborations! #Research #Physics #ParticlePhysics #PTSymmetry #AcademicResearch #arXiv #Collaboration

🚀 New Insights in Optical Physics! 🧬 We are thrilled to announce the publication of a groundbreaking article by Hui Peng in the Advances in Theoretical & Computational Physics (ATCP) journal. 📄 Title: Non-Interference Pattern Evolving to Interference Pattern, Non-Diffraction Pattern Evolving to Diffraction Pattern, and Two Non-Diffraction Patterns Evolving to Diffraction-Interference-Hybrid Pattern - Advances in Optical Experiments Demanding New Theory. 🔍 This work explores fascinating transitions between optical patterns, challenging existing theories and demanding fresh perspectives. It's a must-read for anyone interested in the cutting-edge of optical experiments! Join us in celebrating this significant contribution to the field of #optical #physics. Read the full #article and dive into these revolutionary findings! 🔗https://lnkd.in/gAMyECKG #OpticalPhysics #PhysicsResearch #ScientificInnovation #ATCP #NewTheory

🎉 Congratulations to Zhe Zhang from the LWE – Lab of Wave Engineering - on the successful defense of his PhD thesis “Topological photonic transport in disordered scattering networks” under the supervision of Prof. Romain Fleury. 🔎 This thesis unveils the most robust topological scattering system- anomalous Floquet networks, found by complete simulation and microwave experiments and fully explained by a new renormalization group theory. Such network will be one of the most promising platforms for future wave processing and next generation communication systems, protected by topological physics. 👉 Link to the thesis manuscript: https://lnkd.in/ec5QQnZS

CERN, Fermilab and DESY: how big-science labs are chasing the quantum dream 01 Feb 2024 James Dacey Big-science facilities are often associated with fundamental research. You might picture scientists hunting for elementary particles, or searching to understand the nature of dark matter. But some facilities – especially high-energy physics labs – are also turning their focus to practical applications of quantum physics. The opportunities for science, industry and society are vast.

In the realm of physics, synthetic dimensions (SDs) have emerged as one of the frontiers of active research, offering a pathway to explore phenomena in higher-dimensional spaces, beyond our conventional 3D geometrical space.

This book authored by Ulrich Jentschura (Missouri University of Science and Technology, USA) and Gregory S Adkins (Franklin & Marshall College, USA) introduces readers to a variety of topics surrounding quantum field theory, notably its role in bound states, laser physics, and the gravitational coupling of Dirac particles. It discusses some rather sophisticated concepts based on detailed derivations which cannot be found elsewhere in the literature. It is suitable for undergraduates, graduates, and researchers working on general relativity, relativistic atomic physics, quantum electrodynamics, as well as theoretical laser physics. Quote WH24 for 25% OFF! Read the excellent sample chapters below: 𝐏𝐫𝐞𝐟𝐚𝐜𝐞: https://lnkd.in/gVHZcaFe 𝐂𝐡𝐚𝐩𝐭𝐞𝐫 𝟏 - 𝐈𝐧𝐭𝐫𝐨𝐝𝐮𝐜𝐭𝐢𝐨𝐧: https://lnkd.in/gsncUgnq More about the book: https://lnkd.in/gJXMpN67 #quantumphysics #electrodynamics #laserphysics #atoms #gravity

🔬 Join Us for an Engaging Scientific Talk! 🌟 We are excited to invite you to the upcoming SFB Colloquium featuring Prof. Dr. Tobias Stauber from the Instituto de Ciencia de Materiales de Madrid. 🗓️ Date: Tuesday, 02.07.2024 ⏰ Time: 14:15 🏢 Location: H34 Prof. Stauber will be presenting on the compelling topic of "Nematic versus Triplet Superconductivity in Twisted Bilayer Graphene." Be part of an enlightening session where we explore the phase diagrams of realistic moiré systems, starting from a microscopic tight-binding model for twisted bilayer graphene within the Hartree-Fock approximation. The talk will cover the emergent U(4)-ferromagnet, the symmetry-breaking in real samples, and how this affects the asymmetry between the superconducting phases for electron and hole doping. Additionally, the discussion will extend to the theory of Ising superconductivity in twisted trilayer graphene and how real-space chirality can be measured in linear transport experiments. This is a fantastic opportunity for anyone interested in cutting-edge research in condensed matter physics and materials science. #CondensedMatterPhysics #TwistedBilayerGraphene #NematicSuperconductivity #TripletSuperconductivity #MoiréSystems #MaterialsScience #ScientificResearch #PhysicsTalk #Colloquium #SFB1277 See you there! 🚀

🚀 Proud to Have Completed: Understanding Modern Physics 🌌 I am excited to share that I have successfully completed the "Understanding Modern Physics I: Relativity and Cosmology" course on Coursera, offered by the University of Hong Kong. This course provided profound insights into the fundamental principles of relativity and cosmology, significantly enriching my understanding of the universe. As a student of physics and engineering with a focus on silicon photonics, this knowledge is invaluable and will undoubtedly contribute to my academic and professional journey. The concepts learned have inspired me to think differently and approach problems with a new perspective. Eager to apply these insights to my studies and future projects. Let's continue exploring the cosmos together! #Physics #Relativity #Cosmology #ModernPhysics #ContinuousLearning

I am excited to share that our work on polarization imaging has featured on the cover of Physics Today, 'the most influential and closely followed physics magazine in the world' by the American Institute of Physics (AIP). Johanna Miller's excellent article on our work can be found here: https://lnkd.in/g8TnF4gc . I hope it inspires scientists from other fields, industry professionals, and physics students to learn more about the potential of polarization imaging. 🙂 Link to the original paper: https://lnkd.in/gn6zERgK

"In the realm of physics, synthetic dimensions (SDs) have emerged as one of the frontiers of active research, offering a pathway to explore phenomena in higher-dimensional spaces, beyond our conventional 3D geometrical space. The concept has garnered significant attention, especially in topological photonics, due to its potential to unlock rich physics inaccessible in traditional dimensions. Researchers have proposed various theoretical frameworks to study and implement SDs, aiming at harnessing phenomena like synthetic gauge fields, quantum Hall physics, discrete solitons, and topological phase transitions in four dimensions or higher. Those proposals could lead to new fundamental understandings in physics." #physics #light